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Validation of Intelligent Integrated Management Platform Capabilities based on a Large Virtual HPC Testbed
Seungwoo Rho, Jinseung Ryu, Sangwan Kim, Kwang Jin Oh, MyoungHwan Yoo
http://doi.org/10.5626/JOK.2022.49.4.276
This paper introduces an intelligent integrated management platform developed by itself to manage high-performance computers equipped with board management controller (BMC) functions, and presents large-scale virtual High Performance Computing (HPC) testbeds and experimental results to verify this platform. Intelligent integrated management platforms can monitor and control the hardware sensors of existing high-performance computers using an Intelligent Platform Management Interface (IPMI) to communicate with the BMC. In addition, a separate agent module operated within the controller was developed and applied to expand the function and performance of the BMC in a high performance computer developed in Korea. In this paper, we introduced an intelligent integrated management platform, built 1,200 virtual HPC testbeds, and verified their functions after linking them to the same integrated management platform as the actual physical server.
Network Intelligence based on Network State Information for Connected Vehicles Utilizing Fog Computing
This paper proposes a method taking advantage of Fog computing and SDN in the connected vehicle environment which is having an unstable communication channel and a dynamic topology. For this purpose, the controller should understand the current state of the overall network by maintaining recent network topology, especially, the mobility information of mobile nodes. These are managed by the controller, and are important in unstable conditions in the mobile environment. The mobility levels are divided into 3 categories. We can efficiently exploit that information. By utilizing network state information, we suggest two outcomes. First, we reduce the control message overhead by adjusting the period of beacon messages. Second, we propose a recovery process to prepare the communication failure. We can efficiently recover connection failure through mobility information. Furthermore, we suggest a path recovery by decoupling the cloud level and the fog level in accordance with application data types. The simulation results show that the control message overhead and the connection failure time are decreased by approximately 55% and 5%, respectively in comparison to the existing method.
Efficient Packet Transmission Utilizing Vertical Handover in IoT Environment
The Internet of Things (IoT) has recently been showered with much attention worldwide. Various kinds of devices, communicating with each other in the IoT, demand multiple communication technologies to coexist. In this environment, mobile devices may utilize the vertical handover between different wireless radio interfaces such as Wi-Fi and Bluetooth, for efficient data transfer. In this paper, an IoT broker is implemented to support the vertical handover, which can also support and manage heterogeneous devices and communication interfaces. The handover is activated based on RSSI, Link Quality values, and real time traffic. The experimental results show that the proposed handover system substantially improves QoS in Bluetooth and reduces power consumption in mobile devices as compared with a system using only Wi-Fi.
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